Microwave suppression tunnel and related features

ABSTRACT

A continuous asphalt mix system for using a microwave heating vessel at the point of production that includes a microwave energy suppression tunnel with one or more mesh flaps for substantially reducing or preventing the leakage of microwave energy from a microwave system, while having a continuous flow of product through the vessel and suppression tunnels. The suppression tunnels are installed on the inlet and/or the outlet side of the system and are sized to suppress leakage.

CROSS-REFERENCE TO RELATED APPLICATIONS

The application claims priority to U.S. Provisional Patent Applicationwith Ser. No. 62/869,305 titled “MICROWAVE SUPPRESSION TUNNEL ANDRELATED FEATURES” filed Jul. 1, 2019, the entire contents of which areincorporated by reference for all purposes herein.

BACKGROUND

Microwave energy can be radiated within an enclosure to processmaterials. Molecular agitation within the material resulting from itsexposure to microwave energy provides energy to heat or dry thematerial.

Some government agencies allocate frequency bands centered at 915 MHzand 2450 MHz for use in microwave heating systems. The intensity of themicrowave energy that is permitted to leak is sometimes restricted toless than 10 milliwatts (mW) per centimeter squared.

Many industrial microwave heating applications require that there beaccess apertures into the enclosure so that materials may becontinuously transported utilizing such as, for example, a conveyor unitor other mechanism. There is a desire for suppression of microwaveenergy from these apertures. Continuous microwave heating arrangementshave presented a problem that is more complex than the suppression ofmicrowave energy from a simpler batch microwave system.

While applying microwave heating to moisture-containing particles, aproblem can include preventing microwaves from escaping to an inletand/or an outlet/discharge region from a channel or region where themicrowaves are applied. This can be handled at present by introducingmaterial through a metal grate including two by two inch square metalchannels. The same type of grate and channels can be employed on anoutlet end. However, these grates have limitations. For example,granular materials or particles (such as moisture-laden granularmaterials) are sometimes introduced through a square channel system. Inthese systems, a blockage or slowdown in the process can occur.

Other technological approaches are currently used to prevent the dangerof microwave emissions, but can be less flexible than desirable. Forexample, other ways of suppressing microwave energy from escaping from amicrowave system as a product or material is moving through can include,for example, water jackets or reflectors. There remains a desire toimprove microwave suppression, especially in continuous microwaveheating systems.

SUMMARY

The present disclosure relates to a continuous heating system formanufacturing asphalt mix (in Europe, asphalt mix or finished asphaltmix are typically referred to as bituminous mix or finished bituminousmix; those skilled in the art readily understand this distinction). Inparticular, this disclosure relates to a continuous asphalt mix systemfor using a microwave heating process at the point of production.

Also disclosed are embodiments of a microwave energy suppression tunnelwith one or more flexible or bendable metallic (e.g., steel) coated meshflaps for substantially reducing or preventing the leakage of microwaveenergy from a microwave vessel, e.g., of a conveyor unit, while having acontinuous flow of product or material through the vessel andsuppression tunnels. The suppression tunnels can be installed on theinlet and/or the outlet side of the vessel and are sized to suppressleakage of the product and/or microwaves produced by the microwavesystem, whatever the size of the product.

Stated differently, embodiments of the present invention include theaddition of at least one microwave energy suppression tunnel configuredfor substantially preventing the leakage of microwave energy from one ormore access openings in a microwave energized system while the productor material to be heated is flowing continuously through the microwavevessel, including, for example, a trough of a conveyor unit also fittedwith a helical auger. The suppression tunnel can be used at inletsand/or outlets of the microwave energized system, and in some exampleseach suppression tunnel comprises a rectangular, U-shaped, or othersuitably shaped tunnel about three feet or more in length installed flator at an angle of preferably no more than about 45 degrees with multipleplies or layers of steel or other microwave material, such as metallicshielding mesh attached to the inner top of the rectangular or U-shapedtunnel or trough. The size of object/materials to be heated can be usedas a guideline for adjusting tunnel or trough size for variousembodiments. The tunnel and trough of the heating system can be sizedand shaped differently in various embodiments.

Flexible or bendable mesh shielding (e.g., in the form of flaps) can bespaced at about six-inch intervals and be the same cross-sectional sizeas the tunnel in which they are mounted. Other intervals and spacing arealso contemplated. The shielding mesh preferably operates and absorb,deflect, or block various frequency ranges, preferably from about 1 MHzto 50 GHz in radio frequency (RF) and low frequency (LF) electricfields.

According to a first aspect of the present disclosure, a microwavesuppression system is disclosed. According to the first aspect, themicrowave suppression system includes at least an inlet and an outlet.The microwave suppression system also includes a tunnel within at leastone of the inlet and outlet that comprises at least one movable meshflap within the tunnel. According to the first aspect, the at least onemovable mesh flap is configured to absorb, deflect, or block microwaveenergy. Also according to the first aspect, the at least one movablemesh flap is configured by be deflected as a material passes through thetunnel and then returning to a resting, closed position when thematerial is no longer passing through the tunnel.

According to a second aspect of the present disclosure, an apparatus fortreating material is disclosed. According to the second aspect, theapparatus for treating material includes a conveyor unit including ahelical auger having an auger shaft provided along an auger rotationalaxis, the auger configured to rotate in a direction such that a quantityof material received at the conveyor unit is caused to be transportedaccording the auger rotational axis. Also according to the secondaspect, the apparatus includes at least one microwave energy generator,each microwave energy generator being operatively connected to arespective microwave guide configured to cause microwaves emitted by themicrowave energy generator to heat the material within the conveyor unitby converting the microwaves to heat when absorbed by at least a portionof the quantity of material within the conveyor unit. Also according tothe second embodiments, the quantity of material is heated using themicrowave energy, and the quantity of material is caused to exit theconveyor unit after being heated to a target temperature.

According to a third aspect a method of making a bituminous mix isdisclosed. According to the third aspect, the method includes receivinga quantity of recycled asphalt paving (RAP) at a conveyor unitcomprising an auger, where the RAP passes through at an inlet microwavesuppression tunnel before entering the conveyor unit. The method alsoincludes transporting the quantity of RAP along the conveyor unit bycausing the auger to rotate. The method also includes heating thequantity of RAP within the conveyor unit using at least one microwavegenerator operatively connected to a respective microwave guideconfigured to cause microwaves emitted by the microwave energy generatorto heat the quantity of RAP within the conveyor unit by converting themicrowaves to heat when absorbed by at least a portion of the quantityof RAP within the conveyor unit. The method also includes causing theheated quantity of RAP to exit the conveyor unit through an outletmicrowave suppression tunnel, where the quantity of RAP that exits theconveyor unit is a bituminous mix.

DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side view of a portable, continuous asphalt mix system,according to various embodiments.

FIG. 2 is a side view of trough and suppression tunnel components of thecontinuous asphalt mix system of FIG. 1

FIG. 3 is a top view of the continuous asphalt mix system of FIG. 1.

FIG. 4 is a perspective exploded view of the trough of the continuousmix system of FIG. 1.

FIG. 5 is a top view of the trough of the continuous mix system of FIG.1.

FIG. 6 is a top view of an auger for use with the trough of thecontinuous mix system of FIG. 1.

FIG. 7 is a top view of an alternative configuration of the trough ofthe continuous mix system of FIG. 1.

FIG. 8 is a cross-sectional side view of a U-shaped microwavesuppression tunnel of an outlet side.

FIG. 9 is a cross-sectional top view of the U-shaped microwavesuppression tunnel of FIG. 8.

FIG. 10 is a cross-sectional side view of a U-shaped microwavesuppression tunnel of an inlet side.

FIG. 11 is a cross-sectional side view of a rectangular microwavesuppression tunnel of an inlet side.

FIG. 12 is a cross-sectional top view of a rectangular microwavesuppression tunnel of FIG. 11.

FIG. 13 is a cross-sectional side view of a rectangular microwavesuppression tunnel of an outlet side.

FIG. 14 is a schematic side view of a hardware detail section of anon-looped microwave absorbing flap with a mesh attached to a microwavesuppression tunnel.

FIG. 15A is a cross-sectional end view of a U-shaped microwavesuppression tunnel configuration with a top-mounted pivoting mesh flapin a closed position.

FIG. 15B is a cross-sectional end view of the U-shaped microwavesuppression tunnel configuration of FIG. 15A with the mesh flap in apartially open position.

FIG. 15C is a cross-sectional end view of the U-shaped microwavesuppression tunnel configuration of FIG. 15A with the mesh flap in afully open position.

FIG. 16A is a cross-sectional end view of a rectangular microwavesuppression tunnel configuration with a top-mounted pivoting mesh flapin a closed position.

FIG. 16B is a cross-sectional end view of the rectangular microwavesuppression tunnel configuration of FIG. 16A with the mesh flap in apartially open position.

FIG. 16C is a cross-sectional end view of the rectangular microwavesuppression tunnel configuration of FIG. 16A with the mesh flap in afully open position.

FIG. 17 is a detail view of an RFI shielding mesh according to variousembodiments.

FIG. 18 is another view of the RFI shielding mesh of FIG. 17.

FIG. 19 is a transmission damping chart of the shielding mesh accordingto FIG. 17.

FIG. 20 is a detail view of another shielding mesh according to variousembodiments.

FIG. 21 is another view of the shielding mesh of FIG. 20.

FIG. 22 is a transmission damping chart of the shielding mesh of FIG.20.

DETAILED DESCRIPTION

According to the present disclosure, a problem currently exists in theart relating to microwave emissions escaping a heating system. At highmaterial flow rates in a continuous production system, microwave energyleakage can be particularly undesirable.

According to the present disclosure, various microwave suppressioninlet/outlet tunnels can be sized to accommodate the size of the flow ofwhatever product or material is being processed, such as ReclaimedAsphalt Pavement (RAP) or Reclaimed Asphalt Shingles (RAS), virginaggregate, or sand, all of which can be components of a bituminous mix.In some cases, a microwave heating system of the present disclosure canbe configured to process/heat about 100 tons of RAP per hour or more,although it would be obvious to one skilled in the art that the processcould be scaled to accommodate quantities of less than 100 tons perhour.

One or more microwave suppression systems (e.g., tunnels or chutes)comprising one or more (e.g., flexible and/or movable) fabric and/ormesh flaps can be used at one or more openings within a microwave-basedheating system in order to reduce microwave emissions that wouldotherwise reach the outside of the heating system. Each microwavesuppression system can comprise a flap or series of flaps that arecapable of and configured to cover one or more inlets and/or outletsfrom a microwave heating system. The microwave suppression systems canprevent or suppress the escape of microwave emissions from the heatingsystem. Therefore, one or more of the fabric and/or mesh flaps can bepositioned at outlets and/or inlets of the continuous microwave heatingsystem. Each flap can be generally shaped to conform to a shape of acorresponding suppression tunnel, chute, or the like.

Outlets and/or inlets of the continuous microwave heating system caninclude one or more suppression tunnels. In particular, moisture-ladenmaterial, aggregate, RAP, RAS or other bituminous mix componentparticles or material can be allowed to enter into the heating region ofmicrowave heating while microwaves are simultaneously substantiallyprevented from escaping a heating trough via the suppression tunnelswithin the system. In preferable embodiments, separate suppressionsystems such as tunnels are supplied and connected to both an inlet andan outlet of a system. In other embodiments, additional suppressiontunnels or related features can be included intermediately to the systemsuch that more than two such suppression systems are included in orderto maximize microwave suppression from openings in the system. It isknown that microwave energy is particularly efficient for heating water(e.g., water molecules), which leads to efficient microwave heating ofmaterials that include at least some of such water molecules. Water canescape a material in the gaseous form of steam when the water is heatedto its boiling point (e.g., about 212 degrees Fahrenheit (° F.)). Steamcan escape from a heating system through ventilation, and in some casesby forced ventilation through positive or negative pressure applied tothe system (e.g., a hot air blower or fan to expedite or assistventilation). Vents can also be added to improve ventilation andfacilitate steam escape characteristics. However, excessive quantitiesof water can have a negative effect on heating various RAP, RAS, andother materials. Furthermore, heat exchangers can be used to reclaimheat released as steam (or otherwise) during microwave heatingprocesses, and in particular heat that is emitted from the phase change(e.g., boiling) of water when the material containing at least somewater is heated.

In some typical cases, RAP can be about 3-8% water content, and in othercases emulsified asphalt, which may also include a softening agent, canbe added to improve mixing efficiency. The addition of emulsifiedasphalt containing the softening agent (if used) can contributeadditional water content. The emulsified asphalt and softening agent maybe added at 0.5 to 5% by weight of the solid bituminous mix componentsbeing added to the microwave heating system. The emulsified asphalt andsoftening agent can contain water used to produce the emulsion and thewater content can be typically between 20% and 80% with another,optional component being a blend of asphalt and softening agent. If, forexample 2% of an emulsified asphalt and softening agent that contains50% water is added to the solid bituminous mix components then anadditional 1% water would have been added to the material flowingthrough the heating system. Other amounts of emulsion will incorporatedifferent amounts of water depending on the amount of emulsion added andamount of water present in the emulsion.

Heating a quantity of material or asphalt product (such as RAP) to atemperature above the boiling point of water (about 212° F.) cantherefore be less efficient because the water particles boil off andescape as steam. During heating to certain temperatures, e.g., at orabove a boiling point, the number of small dipole molecules (e.g.,water) that the microwaves can easily heat through oscillation candecrease. Heating of the material or product then becomes reliant on themicrowaves oscillation larger particles which may require more energy.More water is therefore removed from the heated asphalt product asheating temperature increases. A phase change of liquid water to gaseoussteam can occur around 180-200° F., and it can be desirable to heat amaterial, e.g., an asphalt product, to about 225-275° F., according tovarious embodiments. Steam that is produced from the heating can escapethe heating system via vents once the phase change occurs. The steam canexit the system by natural and/or forced ventilation. In some cases,there may be little or no bituminous emissions below about 250° F., orat a maximum below about 270-275° F.

According to various embodiments the material to be heated and/orprocessed is an aggregate material. In certain embodiments the materialcan be various particles, such as particles to be heated. The materialcan be composed of various particulate materials. Examples of theaggregate material can comprise at least some RAP, which can comprisevarious mixtures of the various particulate materials. The RAP cancomprise between 1%-10% asphalt binder for a fractionated ornon-fractionated RAP. Optionally, the RAP comprises aggregate and2.5%-7.0% asphalt binder based on the use of a fractionated ornon-fractionated RAP. In some embodiments the RAP is crushed RAP, milledRAP, or a blend of both.

In some embodiments, the material can comprise a bituminous mix, whichcan comprise virgin aggregate, virgin binder, and/or recycled orreclaimed bituminous materials such as RAP and/or RAS. The material insome embodiments can comprise other non-bituminous material additives toimprove final bituminous mix properties. As used herein, “aggregatematerial” is intended to be used generally, and can refer to anymaterial, particles, mixture, aggregate, or any other suitable materialthat can be heated using microwave energy as described herein. Aggregatematerial can be any flowable material in various embodiments.

In some embodiments, the aggregate material comprises at least somevirgin aggregate material and/or virgin bitumen. In some embodiments, atleast some binder material is added to the aggregate material, e.g.,within the system. In further embodiments, the aggregate materialcomprises at least some additive, such as a recycling additive. Theadditive can be selected from the group consisting of: a recyclingadditive, a compaction aid additive, softening additive, anti-strip, anda cold-weather aid additive. In further embodiments, at least a quantityof virgin aggregate material is added to the aggregate material withinthe system. In yet further embodiments, the aggregate material comprisesat least one of RAS and RAP. In some embodiments, at least one of thegroup consisting of: virgin aggregate, virgin binder, softeningadditive, and age retarding additives is added to a quantity of RAPbefore being caused to exit a conveyor unit. In some examples, the ageretarding additive comprises blends of pure phytosterols or blends ofpure phytosterols and crude sterols, where the crude sterols are derivedfrom tall oil pitch of distillation residue of plant derived oilsincluding soybean oil, corn oil, sunflower seed oil, rape seed oil orsimilar plant derived oils.

In some embodiments, one or more additives can be added to asphaltproducts to be heated and at various stages during processing. Variousadditives can provide a number of different qualities when added tomaterial being processed. For example, additives can increase microwaveenergy absorption and efficiency during heating. Other additives canprovide softening. Some examples of additives include sterol, bitumen,bio-derived products, petroleum-derived products, softening oils, and/orrejuvenating compositions. One illustrative example of an additive thatcan be added to various asphalt products include taconite tailings,and/or minerals that have magnetic qualities such as graphite,magnetite, and hematite, which can have a higher affinity for microwavesyet do not substantially result in the dissipation of heat as thevaporization of water would.

In some embodiments, a continuous microwave heating process can includedwell time, ramp-up time, hold time, and various heating peaks. Mixingof various asphalt products and mixtures can improve performance duringmicrowave heating, according to some embodiments.

A conventional continuous microwave heating system sized in order to geta maximum throughput is limited to the physical size of the productbeing heated and weight per time (e.g., pounds per hour) of saidproduct. This can be due to limitations of existing tunnel design.Therefore, a mesh or fabric flap design of an inlet microwavesuppression tunnel 202 and/or an outlet microwave suppression tunnel200, as shown in FIG. 1, are better suited for high-volume continuousflow of various sized products. Microwave suppression tunnel 200 is anexample of a microwave suppression system as used herein. Also as shownin FIG. 1, multiple flaps can be used in a single microwave suppressiontunnel 200, e.g., four positioned sequentially as shown. Each flap ispreferably shaped to conform to a shape of a corresponding suppressiontunnel 200, chute, or the like.

Drying, heating, and mixing of not only bituminous mix is contemplatedherein, but also the drying of sugar beets, wood pulp, potatoes, corn,oats, other grains, shredded or chipped used tires or any otherparticulate materials that require drying. Additionally, sanitization,pasteurization, etc. of various materials or products is alsocontemplated. Yet additional usages of the present disclosure relates tothe mining industry, such as using microwaves to fracture rock/mineral,etc.

FIGS. 1-7 illustrate an embodiment of a portable, continuous asphalt mixsystem 100 having a vessel or trough 102 comprising a microwave heatedapparatus with one or more microwave heating units each with acorresponding waveguide to define a guide path for a microwave. Asshown, the continuous asphalt mix system 100 also includes an inletsuppression tunnel 202 and an outlet suppression tunnel 200.

An auger 106 or (e.g., a helical screw) is one option for a conveyancemechanism by which particles can be caused to pass through the trough102 longitudinally. The auger 106 can be completely covered in particlesto be heated during operation, but the particles are not shown forclarity. The outlet suppression tunnel 200 can be connected to an outletand/or inlet of trough 102. The trough 102 can be level or can be cantedat an angle to the horizontal plane according to various embodiments.FIGS. 2-7 show various components of the trough 102, auger 106, inletsuppression tunnel 202, outlet suppression tunnel 200, and othercomponents of the system 100 in greater detail. Selected embodiments andvariations of the inlet suppression tunnel 202 and the outletsuppression tunnel 200 and components thereof are shown in yet greaterdetail with respect to FIGS. 8-16C.

Various embodiments of a continuous asphalt mix system 100 include aconveyor unit comprising a vessel or trough 102, one or more microwaveheating units and associated waveguides, an auger 106 or other suitableconveyor system, an inlet suppression tunnel 202, and an outletsuppression tunnel 200. These and other components are described ingreater detail herein.

FIG. 3 shows the general configuration of a continuous heating system100 of the present description, including eight microwave heating units,a microwave waveguide for each heating unit, an auger-based continuousheating assembly, and various other components. In particular, FIG. 3shows an example including eight microwave heating units labeled as XMTR1, XMTR 2, XMTR 3, XMTR 4, XMTR 5, XMTR 6, XMTR 7, and XMTR 8. More orfewer microwave heating units (and corresponding waveguides) can be usedin alternative embodiments. One example microwave heating unit can beprovided by Thermax Thermatron. The microwave heating units can be builtin a large variety of shapes and sizes according to the requirements ofa continuous heating process. Each microwave heating unit can preferablyapply about 100 kW of power to the product being heated and operates atabout 915 MHz.

Various waveguide configurations and embodiments are shown in FIGS. 1and 3. The various waveguides can be configured to bend and be routedsuch that no two waveguides collide, and in some cases the waveguidescan be configured to minimize turns or bends in the waveguides, aspractical.

FIG. 1 is a side view of the continuous heating assembly, including anexample inlet suppression tunnel 202, outlet suppression tunnel 200, andtrough 102 of system 100. Although not shown, the trough 102 can bemounted or positioned at an angle to facilitate asphalt movement orproduction during the heating process, e.g., by at least partiallyutilizing gravity to move the asphalt of other material through thetrough 102.

FIG. 4 is an exploded view of system 100. Shown is a motor for rotatingthe auger 106, the trough 102 for carrying the asphalt to be heated, theinlet suppression tunnel 202, the outlet suppression tunnel 200, andvarious other components. In particular, FIG. 4 provides a more detailedview of trough 102.

Various entry points for microwaves via the multiple waveguides intrough 102 are shown in FIG. 5.

In the configuration of FIG. 6, the trough 102 of the continuous heatingassembly of system 100 includes an auger 106. The auger 106 canoptionally be heated and used to cause asphalt to be heated using liquidand/or microwave heating to be moved longitudinally along the trough 102during heating or production. The auger 106 can also be caused to rotatedirectly or indirectly by a motor or engine, according to variousembodiments. Furthermore, the auger 106 can be caused by themotor/engine to rotate more slowly or more quickly according to variousparameters, which can be based on need or usage. As shown, a fluidconnection can be attached to one or more ends of the auger 106, whichcan be used for additional auger-based heating or cooling of asphaltbeing produced or heated.

FIG. 7 is a top view of an alternative configuration of the trough 102of FIG. 4 where various apertures within an alternative trough 104 coverare instead positioned in alternative locations.

FIG. 8-13 illustrate various arrangements of microwave absorbing,deflecting, or blocking flaps, variously including inlet (e.g., 202) andoutlet suppression tunnel (e.g., 200) embodiments.

FIG. 8 is a cross-sectional side view of a U-shaped microwavesuppression tunnel 200 of an outlet side. As shown, a series of four,single-ply (e.g., single layer) microwave suppression flaps 214 areshown in the outlet suppression tunnel 200 in a down position. Athardware detail section 400 of FIG. 14, flaps 214 can be attached to atop outlet side portion 216 of the outlet suppression tunnel 200 alongwith attachment hardware including bolt fastener 206, nut 208, boltwasher 210, metal bracket 212, and shielding mesh flap 214. As usedherein, the inlet suppression tunnel 202 and the outlet suppressiontunnel 202 can be operatively similar and the features of either can beincorporated into the other in various embodiments. For example,although the inlet suppression tunnel 202 is shown with a single flap218, multiple flaps 218 can be used in the inlet suppression tunnel 202among other features of the outlet suppression tunnel 200.

FIG. 9 is a cross-sectional top view of the U-shaped microwave outletsuppression tunnel 200 of FIG. 8. As shown, multiple attachment points(e.g., using hardware shown at FIG. 14) for each flap 214 arecontemplated, although any suitable attachment or arrangement for theflap 214 is also contemplated herein.

FIG. 10 is a cross-sectional side view of a U-shaped inlet microwavesuppression tunnel 202 for use with or connection to an inlet side of aconveyor unit, such as of the system 100. System 100 described abovewith reference in particular to FIGS. 1-4, can have inlet and outletends of a continuous motion particle pathway (e.g., motivated by auger106 or other conveyance mechanism of the conveyor unit), an inletsuppression tunnel 202 can be used with or without an outlet suppressiontunnel 200 as shown in FIGS. 8 and 9. A single, single-ply (e.g. singlelayer) microwave suppression flap 218 is shown in FIG. 10 attached to atop inlet side portion 217, e.g., using hardware as shown and describedwith respect to FIG. 14, below. As shown in the embodiments of FIGS.8-10, the suppression tunnels 200 and 202 use a single-ply (e.g., singlelayer) microwave-absorbing, deflecting, or blocking mesh flap 214 or218, respectively.

FIGS. 11-13 illustrate alternative embodiments where mesh flap(s) 314,318 are doubled over as two-ply for increased microwave absorption.FIGS. 11-13 are similar to FIGS. 8-10, respectively, with the exceptionof the folded over, two-ply (two layer) mesh flap(s) 314, 318.

FIG. 11 is a cross-sectional side view of a rectangular outlet microwavesuppression tunnel 300. Four flaps 314 are shown, and each flap 314 canbe attached to a top portion 316 of the outlet suppression tunnel 300along with attachment hardware including bolt fastener 206, nut 208,bolt washer 210, metal bracket 212, and shielding mesh flap 314.

FIG. 12 is a cross-sectional top view of the rectangular microwaveoutlet suppression tunnel 300 of FIG. 11. FIG. 13 is a cross-sectionalside view of a corresponding rectangular microwave inlet suppressiontunnel 302. As shown, folded flap 318 is attached to top outlet side317.

FIG. 14 shows greater detail of hardware detail section 400 of FIG. 8.As shown, a flap 214 can be attached to (e.g., a top inlet or outletside portion) of a suppression tunnel along with attachment hardwareincluding bolt fastener 206, nut 208, bolt washer 210, metal bracket212, and shielding mesh flap 214. FIG. 14 shows a side view of anon-looped, single-ply microwave absorbing, deflecting, or blocking flap214 with a microwave-absorbing mesh described in greater detail hereinthat is attached to a tunnel (or chute, etc.). Only one examplefastening arrangement is shown at hardware detail section 400, but otherarrangements are contemplated. In other embodiments, the flap 214 withmesh can be looped, causing a two-ply (e.g., two layer) flap to beattached at two ends in a manner similar to the fastening arrangementshown at hardware detail 400.

Flap 214 as shown in FIG. 14 (and any other embodiments of flaps herein)is preferably electrically grounded to a heating system frame 201. Theheating system frame 201 is preferably grounded to a power sourceelectrical grid (not shown) according to various embodiments.

Turning now to FIGS. 15A-15C and 16A-16C, various cross-sectional endviews are shown that provide detail of flap configuration within amicrowave suppression tunnel or chute in addition to flap articulationor flexing that occurs during continuous material (e.g., asphalt)production and movement along the tunnel.

Inlet and/or outlet tunnels (e.g., 202, 200, etc.) can be positioned andconnected relative to the continuous heating assembly. During heatingoperation, it is possible that at least some microwave energy will notbe absorbed by asphalt being heated or other components within theassembly. This non-absorbed, escaped, or “leaked,” microwave energy canbe unsafe, undesirable, or otherwise beneficial to avoid in practice. Inorder to address this shortcoming, one or more movable and/or pivotableflaps can be positioned at the inlet tunnel, the outlet tunnel, or both.

In various embodiments, an example microwave absorbing, deflecting, orblocking flap, for inlet or outlet of asphalt, can comprise a flexiblemesh configured to feely pivot when contacted by moving aggregatematerial as described herein. Inlet and/or outlet microwave suppressiontunnels can have rounded, rectilinear, or a combination of the two foran outline along the various tunnels.

In various embodiments, suppression tunnels are preferably in asubstantially horizontal position, but preferably at an angle of no morethan 45 degrees from horizontal.

FIG. 15A is a cross-sectional end view of a U-shaped microwavesuppression tunnel configuration 500A with a top-mounted pivoting meshflap 506 in a closed position. Example attachment points 502 show onealternative mounting configuration that allows flap 506 to pivot withinU-shaped flap surround 508. The flap 506 can pivot along a top flapportion or axis 504, or can bend alternatively when a pressure isapplied to the flap 506.

FIG. 15B is a cross-sectional end view of a U-shaped microwavesuppression tunnel configuration 500B, similar to 500A of FIG. 15A withthe mesh flap in a partially open position. As particles are moved alonga trough defined by surround 508, flap 506 can be caused to pivot orbend such that an opening 510 between the flap 506 and the surround 508is revealed. Opening 510 can allow particles to pass while allowingminimal microwaves to escape. Particles causing flap 506 to open can atleast partially block microwaves that would otherwise have escaped themicrowave suppression tunnel (e.g., outlet suppression tunnel 200 orinlet suppression tunnel 202, among other examples described herein).

FIG. 15C is a cross-sectional end view of the U-shaped microwavesuppression tunnel configuration 500C similar to 500A of FIG. 15A withthe mesh flap 506 in a fully open position, causing a larger opening 510than in configuration 500B.

The embodiments shown in FIGS. 15A-15C can also be modified to include arectangular flap 606 with a corresponding rectangular surround 608, asshown in FIGS. 16A-16C.

FIG. 16A is a cross-sectional end view of a rectangular microwavesuppression tunnel configuration 600A with a top-mounted pivoting meshflap 606 in a closed position. Example attachment points 602 show onealternative mounting configuration that allows flap 606 to pivot withinrectangular flap surround 608. The flap 606 can pivot along a top flapportion or axis 604, or can bend alternatively when a pressure isapplied to the flap 606.

FIG. 16B is a cross-sectional end view of a rectangular microwavesuppression tunnel configuration 600B, similar to 600A of FIG. 16A withthe mesh flap in a partially open position. As particles are moved alonga trough defined by surround 608, flap 606 can be caused to pivot orbend such that an opening 610 between the flap 606 and the surround 608is revealed. Opening 610 can allow particles to pass while allowingminimal microwaves to escape. Particles of material causing flap 606 toopen can at least partially block microwaves that would otherwise haveescaped the microwave suppression tunnel.

FIG. 16C is a cross-sectional end view of the rectangular microwavesuppression tunnel configuration 600C similar to 600A of FIG. 16A withthe mesh flap 606 in a fully open position, causing a larger opening 610than in configuration 600B.

Many other microwave suppression system flap and tunnel configurationsare also contemplated herein, and the examples above are merely shown asselected examples of preferred embodiments.

FIGS. 17 and 18 show an example stainless steel RFI shielding mesh 700.The mesh 700 can be a carbon cover metal.

For example, the shielding mesh 700 can be sourced from AaroniaUSA/Aaronia AG. The shielding mesh 700 can be an 80 dB Stainless SteelRFI Shielding Aaronia X-Steel model, which can provide military orindustrial grade screening to meet various demanding usage cases. Insome examples, the shielding mesh 700 can be coated with apolytetrafluoroethylene (i.e., PTFE or “Teflon”) coating. The steel mesh700 can be highly durable, effective up to about 600 degrees Celsius (°C.), operate under a very high frequency range, and be permeable to air.

In more detail, shielding mesh 700 is an Aaronia X-Steel component thatcan operate to at least partially shield both radio frequency (RF) andlow frequency (LF) electric fields. Some specifications of the shieldingmesh 700 can include a frequency range of 1 MHz to 50 GHz, a damping indecibels (dB) of 80 dB, a shielding material including stainless steel,a carrier material including stainless steel, a color of stainless steel(silver), a width of 0.25 m or 1 m or some variation, a thickness ofabout 1 mm, available sizes of about 0.25 m² or 1 m², a mesh size ofapproximately 0.1 mm (multiple ply/layer), and a weight of approximately1000 g/m². The shielding mesh 700 can be suitably durable, and can beconfigured and rated for use in industrial or other applications, canhave a temperature range up to 600° C., can be permeable to air, andpermit very easy handling.

In some examples, the shielding mesh 700 can be EMC screening AaroniaX-Steel from Aaronia AG, which can be made from 100% stainless steelfiber. The shielding mesh 700 can meet various industrial or militarystandards. The shielding mesh 700 can be very temperature stable for atleast 600° C., does not rot, and is permeable to air. The shielding mesh700 can be suitable for EMC screening of air entrances and can be veryhigh protective EMC clothing, etc. The shielding mesh 700 can protectagainst many kinds of RF fields and can offer a 1000-fold bettershielding-performance and protection especially in the very high GHzrange as compared to various other types of shielding mesh. Theshielding mesh 700 provides screening within the air permeable EMCscreening materials.

Application examples of the shielding mesh 700 include: Radio & TV,TETRA, ISM434, LTE800, ISM868, GSM900, GSM1800, GSM1900, DECT, UMTS,WLAN, etc.

FIG. 19 shows a transmission damping chart 702 for various shieldingmesh examples from 1-10 GHz in terms of dB for the mesh 700 of FIGS. 17and 18. As shown, four shielding meshes are depicted. As shown, indescending order for transmission damping across 1-10 GHz, are AaroniaX-Dream, Aaronia X-Steel, Aaronia-Shield, and A2000+.

FIGS. 20 and 21 show another example shielding mesh, a fireproofshielding fabric mesh 800.

The fireproof shielding fabric mesh 800 can be sourced from Aaronia AG,and is a stainless steel EMC/EMF shielding mesh for usage under extremeconditions. The fireproof shielding mesh 800 is usable up to 1200° C.,can be half transparent, has high attenuation, and is both odorless androt resistant. The fireproof shielding fabric mesh 800 has microwaveattenuation as follows: 108 dB at 1 kHz, 100 dB at 1 MHz, 60 dB at 100MHz, 44 dB at 1 GHz, 30 dB at 10 GHz.

Some specifications of the fireproof shielding fabric mesh 800 include:lane Width: 1 m; thickness: 0.2 mm; mesh size: about 0.1 mm; color:stainless steel; weight: approx., 400 g/m; usable until about 1200° C.;yield strength: 220 MPa; tensile strength: 550 MPa; hardness: 180 HB;can be breathable, odorless; transparent rot resistant; frost proof;washable; foldable; bendable; mesh material: stainless steel.

The fireproof shielding fabric mesh 800 has screening performance forstatic fields of: 99.9999% to 99.99999% (e.g., when grounded). Thefireproof shielding fabric mesh 800 has screening performance for lowelectric fields of: 99.9999% to 99.99999% (e.g., when grounded).

The fireproof shielding fabric mesh 800 is suitable for industrialapplications as well as for research and development. The fireproofshielding fabric mesh 800 has been specifically designed for use widervarious adverse conditions (salt air, extreme temperatures, vacuum,etc.).

The fireproof shielding fabric mesh 800 is made of 100% stainless steel,is temperature stable up to 1200° C., has high microwave attenuation,and is breathable. The material of mesh 800 absorbs reliable E&H fields.In particular, in the kHz and low MHz range mesh 800 offers a highshielding factor of up to 108 dB (E-field). Mesh 800 is easy to processand can be cut with a standard pair of scissors.

FIG. 22 is a transmission damping chart 802 from 1-10 GHz in terms of dBfor the fireproof mesh 800 of FIGS. 20 and 21.

Based on power requirements, two or more microwave power units can beinstalled on the same auger or conveyor. To assure uniform heatdistribution in a large variety of load configurations, a multimodecavity can be provided with a waveguide splitter with dual microwavefeed points and/or mode stirrers.

The product or material being heated can be carried in various examplesby another type of conveyance mechanism, such as by a unique conveyorbelt. Therefore, in some embodiments a conveyorized modular industrialmicrowave power system can be employed as alternative to an auger-basedsystem such as system 100. The belt material and configuration areselected based on the nature of the product being heated. Each end ofthe conveyor is preferably also provided with a special vestibule tosuppress any microwave leakage. Air intake and exhaust vents or portsare provided for circulating air to be used in cases where vapors orfumes are developed during the heating process.

Common uses of the microwave power system include drying or heating.Applications of the microwave power system include ceramics, catalysts,vulcanizing, composites, bulk fibrous components, sand cores, generaldrying and heating of electrically non-conductive materials, andresearch and development.

Unlike home microwave ovens, example industrial microwave systemscontemplated herein preferably separate microwave generation from aheating/drying cavity such as a trough or housing. An example industrialmicrowave heating system can be constructed to use one or more microwavegenerator units. Example microwave generator units come in 75 kW and 100kW (output power) models. Using special ducts called waveguides ormicrowave guides, the microwave energy is carried to one or moreindustrial microwave cavities. An example cavity is about twelve feetlong and five feet wide. In a conveyor belt-based embodiment, a conveyorbelt, auger, etc. carries the product through the cavities. A simpleexample system may include one microwave generator and one cavity, whilea larger and/or more complex system may have a dozen generators and sixcavities. This inherent modularity provides great flexibility in scalinga system, or building systems, which can be easily expanded in thefuture.

These and other advantages will be apparent to those of ordinary skillin the art. While the various embodiments of the invention have beendescribed, the invention is not so limited. Also, the method andapparatus of the present invention is not necessarily limited to anyparticular field, but can be applied to any field where an interfacebetween a user and a computing device is applicable.

The disclosures of published PCT patent applications, PCT/US2017/023840(WO2017165664), PCT/US2013/039687 (WO2013166489), and PCT/US2013/039696(WO2013166490) are hereby incorporated by reference.

In alternative embodiments, example microwave suppression flap(s) can berigid and non-flexible, but can be attached to top portion using hingesor any other articulating hardware as known in the art. Alternativehardware and flap fastening arrangements are also contemplated.

Unless otherwise defined, all technical and scientific terms used hereinhave the same meaning as commonly understood by one of ordinary skill inthe art to which this invention belongs. Although methods and materialssimilar to or equivalent to those described herein can be used in thepractice or testing of the present invention, suitable methods, andmaterials are described below. All publications, patent applications,patents, and other references mentioned herein are incorporated byreference in their entirety to the extent allowed by applicable law andregulations. In case of conflict, the present specification, includingdefinitions, will control.

The present invention may be embodied in other specific forms withoutdeparting from the spirit or essential attributes thereof, and it istherefore desired that the present embodiment be considered in allrespects as illustrative and not restrictive, reference being made tothe appended claims rather than to the foregoing description to indicatethe scope of the invention. Those of ordinary skill in the art that havethe disclosure before them will be able to make modifications andvariations therein without departing from the scope of the invention.

1. A microwave suppression system, comprising: at least an inlet and anoutlet; and a tunnel within at least one of the inlet and outlet thatcomprises at least one movable mesh flap within the tunnel, wherein theat least one movable mesh flap is configured to absorb, deflect, orblock microwave energy, and wherein the at least one movable mesh flapis configured to be deflected as a material passes through the tunneland then to return to a resting, closed position when the material is nolonger passing through the tunnel.
 2. The microwave suppression systemof claim 1, wherein the movable mesh flap is made of stainless steel. 3.An apparatus for treating material, comprising: a conveyor unitcomprising a helical auger having an auger shaft provided along an augerrotational axis, the auger configured to rotate in a direction such thata quantity of material received at the conveyor unit is caused to betransported according the auger rotational axis; and at least onemicrowave energy generator, each microwave energy generator beingoperatively connected to a respective microwave guide configured tocause microwaves emitted by the microwave energy generator to heat thematerial within the conveyor unit by converting the microwaves to heatwhen absorbed by at least a portion of the quantity of material withinthe conveyor unit; wherein the quantity of material is heated using themicrowave energy, and wherein the quantity of material is caused to exitthe conveyor unit after being heated to a target temperature.
 4. Theapparatus of claim 3, wherein the auger shaft defines an internal augerfluid path provided along the auger rotational axis, and furthercomprising a fluid management device configured to heat the auger andtransfer heat to the quantity of material through the auger, wherein thequantity of material is heated using a combination of the microwaveenergy and fluidic heat.
 5. The apparatus of claim 3, furthercomprising: a material inlet and a material outlet; a tunnel within atleast one of the material inlet and material outlet that comprises amicrowave suppression system; at least one movable mesh flap within thetunnel, wherein the at least one mesh flap is configured to absorb,deflect, or block microwave energy, and wherein the at least one movablemesh flap is configured by be deflected as the material passes throughthe tunnel and then returning to a resting, closed position when thematerial is no longer passing through the tunnel.
 6. The apparatus ofclaim 5, wherein the movable mesh flap is made of stainless steel.
 7. Amethod of making a bituminous mix, comprising: receiving a quantity ofrecycled asphalt paving (RAP) at a conveyor unit comprising an auger,wherein the RAP passes through at an inlet microwave suppression tunnelbefore entering the conveyor unit; transporting the quantity of RAPalong the conveyor unit by causing the auger to rotate; heating thequantity of RAP within the conveyor unit using at least one microwavegenerator operatively connected to a respective microwave guideconfigured to cause microwaves emitted by the microwave energy generatorto heat the quantity of RAP within the conveyor unit by converting themicrowaves to heat when absorbed by at least a portion of the quantityof RAP within the conveyor unit; and causing the heated quantity of RAPto exit the conveyor unit through an outlet microwave suppressiontunnel, wherein the quantity of RAP that exits the conveyor unit is abituminous mix.
 8. The method of claim 7, wherein the quantity of RAP isheated to a target temperature before being caused to exit the conveyorunit.
 9. The method of claim 7, wherein at least one of the groupconsisting of: virgin aggregate, virgin binder, softening additive, andage retarding additives is added to the quantity of RAP before beingcaused to exit the conveyor unit.
 10. The method of claim 9, wherein theage retarding additive comprises blends of pure phytosterols or blendsof pure phytosterols and crude sterols, and wherein the crude sterolsare derived from tall oil pitch of distillation residue of plant derivedoils selected from the group consisting of: soybean oil, corn oil,sunflower seed oil, and rape seed oil.
 11. The method of claim 7,wherein the inlet suppression tunnel comprises: at least one inletmovable mesh flap within the inlet suppression tunnel, wherein the atleast one inlet movable mesh flap is configured to absorb, deflect, orblock microwave energy, and wherein the at least one inlet movable meshflap is configured to be deflected as the quantity of RAP passes throughthe inlet suppression tunnel and then to return to a resting, closedposition when the quantity of RAP is no longer passing through the inletsuppression tunnel.
 12. The method of claim 11, wherein the inletmovable mesh flap is made of stainless steel.
 13. The method of claim 7,wherein the outlet suppression tunnel comprises: at least one outletmovable mesh flap within the outlet suppression tunnel, wherein the atleast one outlet movable mesh flap is configured to absorb, deflect, orblock microwave energy, and wherein the at least one outlet movable meshflap is configured to be deflected as the quantity of RAP passes throughthe outlet suppression tunnel and then to return to a resting, closedposition when the quantity of RAP is no longer passing through theoutlet suppression tunnel.
 14. The method of claim 13, wherein theoutlet movable mesh flap is made of stainless steel.